Optical component bowing device, optical device, optical scanning device, and image forming apparatus

ABSTRACT

An optical component bowing device includes a bending moment generating structure. In a particular embodiment, the bending moment generating structure can have extension members that extend in a direction substantially orthogonal to a longitudinal direction of an optical component. The extension members can be positioned adjacent longitudinal end portions of the optical component. The bending moment generating structure can also have loading members that load the extension members in a direction that is parallel to a longitudinal direction of the optical component, whereby displacement of the extension members can generate a bending moment in a supported portion of the optical component that reflects or shapes a light beam. The bending moment generating structure can also include a reflective surface. Extension members on at least one end of the optical component can be T-shaped when seen in plan view in a direction orthogonal to the reflective surface.

CROSS-REFERENCE TO RELATED APPLICATION

The present application is a continuation of U.S. patent applicationSer. No. 11/783,769, filed on Apr. 12, 2007, which is based on andclaims priority under 35 USC 119 from Japanese Patent Application No.2006-232518 filed on Aug. 29, 2006. The contents of both priorapplications are hereby incorporated by reference in their entirety.

BACKGROUND

1. Technical Field

The present invention relates to an optical component bowing device, anoptical device, an optical scanning device, and an image formingapparatus.

2. Related Art

In an optical scanning device that emits a light beam, a cylindricallens or the like is caused to bow to correct the scanning position in adirection orthogonal to the scanning direction of the light beam on aphotoconductor.

SUMMARY

An optical component bowing device of a first aspect of the inventionincludes a bending moment generating structure that generates a bendingmoment in a supported portion of an optical component that reflects orshapes a light beam.

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the present invention will be described indetail based on the following figures, wherein:

FIG. 1 is a general configural diagram of an image forming apparatusdisposed with an optical scanning device pertaining to a first exemplaryembodiment of the invention;

FIG. 2 is a diagram schematically showing, in plan view, relevantportions of the optical scanning device pertaining to the firstexemplary embodiment of the invention;

FIG. 3A is a perspective diagram showing a cylindrical mirror, and FIG.3B is a plan diagram showing a state where the cylindrical mirror isbowed;

FIG. 4 is a diagram schematically showing, in plan view, relevantportions of an optical scanning device pertaining to a second exemplaryembodiment of the invention;

FIG. 5 is a diagram schematically showing, in plan view, relevantportions of an optical scanning device pertaining to a third exemplaryembodiment of the invention;

FIG. 6 is a perspective diagram schematically showing relevant portionsof an optical scanning device pertaining to a fourth exemplaryembodiment of the invention; and

FIG. 7A and FIG. 7B are explanatory diagrams describing bow correction.

DETAILED DESCRIPTION

In FIG. 1, there is shown the general configuration of an image formingapparatus 12 disposed with an optical scanning device 14 pertaining to afirst exemplary embodiment of the present invention. The image formingapparatus 12 is a tandem full-color image forming apparatus where pluralphotoconductors are juxtaposed, toner images of respective colors areformed on the photoconductors, and then the respective color tonerimages are superposed to form a full-color toner image.

Below, when members are to be distinguished by color, the letters C(cyan), M (magenta), Y (yellow), and Bk (black) will be added toreference numerals representing those members. When it is notparticularly necessary to distinguish between the members by color, theletters C, M, Y, and Bk will be omitted. Further, the direction in whichlight beams scan optical components will be referred to as a scanningdirection.

The optical scanning device 14 includes a box-shaped optical box 50.Housed inside the optical box 50 are various kinds of optical componentssuch as light source members 18C, 18M, 18Y, and 18Bk, plane mirrors 20,plane mirrors 22, a rotating polygon mirror 24, an fθ lens group 26,plane mirrors 28C, 28M, 28Y, and 28Bk, and cylindrical mirrors 30C, 30M,30Y, and 30Bk having an imaging function in a direction orthogonal tothe scanning direction.

A semiconductor laser 32, a collimator lens 34, an aperture 36, and acylindrical lens 38 having an imaging function in one direction aredisposed inside each of the light source members 18C, 18M, 18Y, and 18Bk(in FIG. 1, just the components of the light source member 18C areshown). A light beam is emitted from the semiconductor laser 32 incorrespondence to image information of each color and is shaped by thecollimator lens 34 having a light beam shaping function. The beam widthof the light beam is made into a predetermined width by the aperture 36,and the light beam is focused by the cylindrical lens 38 in a directioncorresponding to the direction in which the light beam moves in thecircumferential direction with the rotation of a later-describedphotoconductor 40.

The light beams emitted from the light source members 18M and 18Y arereflected by the plane mirrors 20 and the plane mirrors 22 and madeincident on a mirror surface 24R of the rotating polygon mirror 24.Further, the light beams emitted from the light source members 18C and18Bk are reflected by the plane mirrors 22 and made incident on themirror surface 24R of the rotating polygon mirror 24.

The rotating polygon mirror 24 is disposed in the center portion of theoptical box 50 such that its rotational axis Y coincides with thevertical direction (the direction of gravitational force), and therotating polygon mirror 24 is rotated about the rotational axis Y by anunillustrated rotary drive device. The light beams made incident on themirror surface 24R of the rotating polygon mirror 24 are deflected bythe movement of the mirror surface 24R resulting from the rotation ofthe rotating polygon mirror 24.

The light beams deflected by the rotating polygon mirror 24 aretransmitted through the fθ lens group 26 having an imaging function, arerespectively reflected by the plane mirrors 28C, 28M, 28Y, and 28Bkcorresponding to each color, and are further reflected by thecylindrical mirrors 30C, 30M, 30Y, and 30Bk. It will be noted that arrowS represents the scanning direction in which the light beams scan thecylindrical mirrors 30C, 30M, 30Y, and 30Bk.

Surfaces of photoconductors 40C, 40M, 40Y, and 40Bk corresponding toeach color and disposed below the optical scanning device 14 are exposedto the light. At this time, due to the rotation of the rotating polygonmirror 24 and the fθ lens group 26, the light beams scan the surfaces ofthe photoconductors 40C, 40M, 40Y, and 40Bk at substantially uniformvelocities in the axial direction.

It will be noted that, when seen in plan view, the cylindrical mirrors30C, 30M, 30Y, and 30Bk are disposed juxtaposed in a single row parallelto each other (see FIG. 2).

The photoconductors 40C, 40M, 40Y, and 40Bk are shaped like drums, andtheir longitudinal directions (axial directions of the drums) coincidewith the scanning direction. When the image forming apparatus 12 is seenfrom the side in the scanning direction, the photoconductors 40C, 40M,40Y, and 40Bk are disposed juxtaposed in a single line withpredetermined intervals interposed therebetween.

The surfaces of the photoconductors 40C, 40M, 40Y, and 40Bk are chargedby charging devices (not shown). When the photoconductors 40C, 40M, 40Y,and 40Bk rotate, the light beams to which the surfaces of thephotoconductors 40C, 40M, 40Y, and 40Bk are exposed (scanned) relativelymove in the circumferential direction. Electrostatic latent images areformed on the surfaces of the photoconductors 40C, 40M, 40Y, and 40Bk asa result of the surfaces of the photoconductors 40C, 40M, 40Y, and 40Bkbeing exposed to the light beams in this manner.

The electrostatic latent images on the photoconductors 40C, 40M, 40Y,and 40Bk are made visible by developing devices (not shown)corresponding to each color, whereby toner images of the respectivecolors are formed on the photoconductors 40C, 40M, 40Y, and 40Bk.

The color toner images formed on the respective photoconductors 40C,40M, 40Y, and 40Bk are sequentially transferred to an intermediatetransfer body such as an endless intermediate transfer belt (not shown),and the four colors are superposed to form a full-color image on theintermediate transfer belt. Then, the full-color image formed on theintermediate transfer belt is transferred all at once to a recordingmedium and fixed by a fixing device (not shown) to the recording medium,so that a desired full-color image can be obtained on the recordingmedium.

Next, the cylindrical mirrors 30C, 30M, 30Y, and 30Bk will be described.Because the cylindrical mirrors 30C, 30M, 30Y, and 30Bk corresponding tothe respective colors all have the same configuration, they will bedescribed without distinguishing between them by color.

As shown in FIG. 3A, a reflective surface 102 of each of the cylindricalmirrors 30 has power just in a direction orthogonal to the scanningdirection (arrow S) (i.e., a direction corresponding to the direction inwhich the light beam moves in the circumferential direction with therotation of the photoconductor 40), and the reflective surface 102corrects variations in the scan line resulting from optical face tangleerror in the mirror surface 24R (see FIG. 1) of the rotating polygonmirror 24 (optical face tangle error correction). The cylindrical mirror30 includes a quadrangular prism-shaped mirror body 104 disposed withthe reflective surface 102 on one side. It will be noted that thelongitudinal direction of the mirror body 104 coincides with thescanning direction represented by arrow S. Further, in FIG. 3A and FIG.3B, the orientation of the reflective surface 102 is shown oppositelyfrom the orientation shown in FIG. 1 and FIG. 2 (i.e., in FIG. 1 andFIG. 2, the reflective mirror 102 faces down).

Extension members 150A and 150B that extend toward mutually oppositesides in a direction substantially orthogonal to the longitudinaldirection (scanning direction) when seen in plan view in a directionorthogonal to the reflective surface 102 are disposed on an end portionon one longitudinal direction side (scanning start side) of the mirrorbody 104 (when it is not necessary to distinguish between the two, theywill be referred to simply as the extension members 150). Similarly,extension members 160A and 160B are also disposed on the end portion onthe other side (scanning end side) (similarly, when it is not necessaryto distinguish between the two, they will be referred to simply as theextension members 160). Thus, each of the end portions on the one sideand on the other side of the cylindrical mirror 30 is shaped like a Twhen seen in plan view in the direction orthogonal to the reflectivesurface 102. It will be noted that the extension members 150 and 160 aredisposed further outside in the scanning direction than the reflectivesurface 102.

Further, by “substantially orthogonal” is meant an angular range of anangle of 90°±3°. It will be noted that it is alright even if theextension members 150 and 160 are not substantially orthogonal to thelongitudinal direction. It suffices as long as the extension membersextend in a direction intersecting the longitudinal direction (scanningdirection). It is also alright even if the extension member 150A and theextension member 150B (and the extension member 160A and the extensionmember 160B) are not formed on the same straight line. For example, theextension member 150A and the extension member 150B (and the extensionmember 160A and the extension member 160B) may also form an angle (likean L shape). Further, the extension members may also be curved ratherthan being straight. Moreover, it is alright even if just one of theextension member 150A and the extension member 150B (and the extensionmember 160A and the extension member 160B) is disposed.

In the present exemplary embodiment, after the mirror body 104 and theextension members 150 and 160 have been formed as separate components,the mirror body 104 and the extension members 150 and 160 are joinedtogether by adhesion or some other method so that the mirror body 104and the extension members 150 and 160 are integrally configured. It willbe noted that the mirror body 104 and the extension members 150 and 160may also be formed as an integral mold.

Support holes 110 and 112 are formed in the longitudinal directioncenter sides of the end portions of the one side and the other side ofthe mirror body 104. Either one of the support holes 110 and 112 is anelongate hole whose longitudinal direction coincides with thelongitudinal direction (scanning direction) of the cylindrical mirror30. In the present exemplary embodiment, the support hole 110 on the oneside is an elongate hole. Support pins 111 and 113 fixed to the opticalbox 50 (see FIG. 1) respectively pass through these two support holes110 and 112 so that the cylindrical mirror 30 is supported in theoptical box 50.

Further, through holes 120A, 120B, 130A, and 130B that penetrate theextension members 150A, 150B, 160A, and 160B are formed in longitudinaldirection center sides from the end portions (in the vicinities of theend portions) of the extension members 150A, 150B, 160A, and 160B.

Additionally, as represented by arrow F1 in FIG. 3B, when a load isapplied from the outsides to the insides of the extension members 150Aand 160A to cause the extension members 150 and 160 to be displaced inthe scanning direction, a bending moment is generated in the portions ofthe support holes 110 and 112. The cylindrical mirror 30 is caused bythis bending moment to bow (in order to make it easier to understand, inFIG. 3B the cylindrical mirror 30 is shown as being bowed more greatlythan in actuality). It will be noted that, as represented by arrow F2, aload may also be applied from the insides to the outsides of theextension members 150B and 160B to cause the extension members 150 and160 to be displaced.

Further, when a load that is opposite from the directions of arrows F1and F2 is applied, the cylindrical mirror 30 bows oppositely from thatshown in FIG. 3B (i.e., with respect to FIG. 3B, the cylindrical mirror30 would bow such that its convex side faces up).

As shown in FIG. 2, both longitudinal direction end portions of each ofthe cylindrical mirrors 30Bk, 30Y, 30M, and 30C project from windows56Bk, 56Y, 56M, and 56C formed in side surface portions 52 and 54 of theoptical box 50. In other words, the extension members 150Bk, 150Y, 150M,and 150C are exposed to the outside of the optical box 50. It will benoted that the gaps between the windows 56Bk, 56Y, 56M, and 56C and thecylindrical mirrors 30Bk, 30Y, 30M, and 30C are sealed with a sealingmember (not shown) such that external dust or the like does not enterinto the optical box 50.

As shown in FIG. 3A and FIG. 3B, the through holes 120A, 120B, 130A, and130B are formed in the longitudinal direction (scanning direction) inboth end portions of the extension members 150 and 160 of each of thecylindrical mirrors 30. Screws 125 are passed through the through holes120A, 120B, 130A, and 130B and screwed into screw holes (not shown) inthe side surface portions 52 and 54 of the optical box 50.

By adjusting how much the screws 125 are screwed into the screw holes inthe side surface portions 52 and 54, the extension members 150 and 160are displaced in the scanning direction and the cylindrical mirror 30bows (see FIG. 3B). It will be noted that the bowing direction (i.e.,the direction that the convex side of the cylindrical mirror 30 faces)may be either up or down in FIG. 2.

As mentioned above, the image forming apparatus 12 of the presentexemplary embodiment superposes respective color toner images to form afull-color image. Thus, when the respective color toner images are notprecisely superposed, color misregistration occurs.

One cause of color misregistration is, as shown in FIG. 7A, when scanlines (BOW(Bk) to BOW(C)) of the light beams scanning thephotoconductors 40Bk, 40Y, 40M, and 40C become bowed in the directionorthogonal to the scanning direction (i.e., the direction in which thelight beams move in the circumferential direction with the rotation ofthe photoconductors 40) with respectively different curvatures. For thisreason, as shown in FIG. 7B, bow correction for correcting and matchingup the bowing of the scan lines (BOW(Bk) to BOW(C)) is performed tocorrect color misregistration.

Additionally, in the image forming apparatus 12 of the present exemplaryembodiment, bow correction is performed (see FIG. 3B) by adjusting howmuch the screws 125 are screwed into the screw holes in the side surfaceportions 52 and 54 of the optical box 50 and adjusting the scanningdirection displacement amounts of the extension members 150Bk, 150Y,150M, and 150C of the cylindrical mirrors 30Bk, 30Y, 30M, and 30C—thatis, the bending moment generated in the support holes 110 and 112 ineach of the cylindrical mirrors 30Bk, 30Y, 30M, and 30C—to adjust thebowing amounts of the cylindrical mirrors 30Bk, 30Y, 30M, and 30C.

In the present exemplary embodiment, as shown in FIG. 2, the extensionmembers 150 and 160 of each of the cylindrical mirrors 30 are exposedfrom the side surface portions 52 and 54 of the optical box 50, but theinvention is not limited to this. The extension portions 150 and 160 ofthe cylindrical mirrors 30 may also be disposed inside the optical box50.

Further, the screws 125 are screwed into screw holes in the side surfaceportions 52 and 54 to cause the extension members 150 and 160 of thecylindrical mirrors 30 to be displaced, but the invention is not limitedto this. Screw holes may also be formed in sites other than the opticalbox 50 and screws may be screwed into those screw holes to cause theextension members 150 and 160 to be displaced.

Next, an optical scanning device 214 of a second exemplary embodimentpertaining to the present invention will be described. It will be notedthat description that is redundant with the description of the firstexemplary embodiment will be omitted.

As shown in FIG. 4, extension members 250 and 260 are alternatelydisposed on either one of the one side (scanning start side) and theother side (scanning end side) of adjacent cylindrical mirrors 230.Specifically, an extension member 250Bk is disposed on the end portionon the one side of a cylindrical mirror 230Bk, an extension member 260Yis disposed on the end portion on the other side of a cylindrical mirror230Y, an extension member 250M is disposed on the end portion on the oneside of a cylindrical mirror 230M, and an extension member 260C isdisposed on the end portion on the other side of a cylindrical mirror230C.

Additionally, the extension members 250 and the extension members 260 ofthe cylindrical mirrors 230 that are adjacent when seen in the scanningdirection (arrow S) are disposed so as to overlap each other.

Further, the extension members 250 and 260 of the cylindrical mirrors230 are exposed from side surface portions 272 and 274 of an optical box270. Screws 125 are screwed into screw holes in the side surfaceportions 272 and 274 to cause the extension members 250 and 260 of thecylindrical mirrors 230 to be displaced in the scanning direction.

It will be noted that in the present exemplary embodiment also, similarto the first exemplary embodiment, the extension members 250 and 260 ofthe cylindrical mirrors 230 may also be disposed inside the optical box270. Further, screw holes may be disposed in sites other than theoptical box 270 and the screws 125 may be screwed into these screw holesto cause the extension members 250 and 260 to be displaced.

Next, an optical scanning device 314 of a third exemplary embodimentpertaining to the present invention will be described. It will be notedthat description that is redundant with the description of the firstexemplary embodiment will be omitted.

As shown in FIG. 5, extension members 350 and 360 of cylindrical mirrors330 are exposed from side surface portions 352 and 354 of an optical box370.

The extension members 350 on the one side (scanning start side) of thecylindrical mirrors 330 and the extension members 360 on the other side(scanning end side) of the cylindrical mirrors 330 are coupled togetherby linear members 332 such as wires or piano wires. Additionally, thelengths of the linear members 332 are adjusted (shortened)—that is, thedistances between the extension members 350 on the one side of thecylindrical mirrors 330 and the extension members 360 on the other sideof the cylindrical mirrors 330 are adjusted (shortened)—to cause theextension members 350 and 360 to be displaced and to cause thecylindrical mirrors 330 to bow.

Further, the linear expansion coefficients of the linear members 332Bk,332Y, 332M, and 332C are caused to vary, for example, in response todifferences in temperature change and differences in length. Forexample, the linear expansion coefficients of the linear members 332Bk,332Y, 332M, and 332C are selected in accordance with differences intemperature rises in places where the cylindrical mirrors 330Bk, 330Y,330M, and 330C are disposed. In other words, the linear expansioncoefficients are made smaller in places where the temperature rise isgreater. For example, the linear expansion coefficients of the linearmembers 332 are selected in accordance with the distance from a heatsource such as the fixing device that fixes the full-color toner imageto the recording medium. For example, assuming that the cylindricalmirror 330Bk is the closest to the heat source and that the cylindricalmirror 330C is the farthest from the heat source, then the linearexpansion coefficient of the linear member 332Bk is made the smallest,and the linear expansion coefficients are made greater from there on inthe order of the linear member 332Y, the linear member 332M, and thelinear member 332C.

Examples of materials for the linear members 332 whose linear expansioncoefficients are different include the following.

stainless steel wires (according to Japan Industrial Standards (JIS))

SUS304: 1.73(×10⁻⁵)

SUS316: 1.60(×10⁻⁵)

SUS430: 1.04(×10⁻⁵)

phosphor bronze wires: 1.80(×10⁻⁵)

hard steel wires: 1.20 (×10⁻⁵)

It will be noted that because the linear members 332 such as wires orpiano wires can only cause the extension members 350 and 360 to bedisplaced in the direction in which the distances between the extensionmembers 350 and the extension members 360 are narrowed, the extensionmember 350A and the extension member 360A, or the extension member 350Band the extension member 360B, are coupled together on the opposite sideof the direction in which one wishes the cylindrical mirrors 330 to bowin convex shapes. In FIG. 5, the cylindrical mirror 330Bk and thecylindrical mirror 330Y bow in convex shapes downward in FIG. 5, and thecylindrical mirror 330M and the cylindrical mirror 330C bow in convexshapes upward in FIG. 5.

In the present exemplary embodiment, the extension members 350 on theone side of the cylindrical mirrors 330 and the extension members 360 onthe other side of the cylindrical mirrors 330 are coupled together bythe linear members 332 such as wires or piano wires, but the inventionis not limited to this. It suffices as long as coupling members coupletogether the extension members 350 on the one side and the extensionmembers 360 on the other side and have lengths that are adjustable. Forexample, rod-shaped coupling members may also be used. In the case ofrod-shaped coupling members, the distances between the extension members350 and the extension members 360 may be increased to cause theextension members 350 and 360 to be displaced.

Further, in the present exemplary embodiment also, similar to the firstexemplary embodiment and the second exemplary embodiment, the extensionmembers 350 and 360 of the cylindrical mirrors 330 may also be disposedinside the optical box 370.

Next, an optical scanning device 414 of a fourth exemplary embodiment ofthe present invention will be described.

As shown in FIG. 6, a resin cylindrical lens 430 for performing opticalface tangle error correction is disposed in the optical scanning device414. In FIG. 6, just one cylindrical lens 430 is shown, but inactuality, similar to the first exemplary embodiment, four are disposedin correspondence to the respective colors.

As shown in FIG. 6, a lens body 432 of the cylindrical lens 430 has aquadrangular prism shape whose longitudinal direction coincides with thescanning direction. Convex portions 440 and 442, in which support holes441 and 443 are formed in a direction orthogonal to the scanningdirection (i.e., a direction corresponding to the direction in which thelight beam moves in the circumferential direction in accompaniment withthe rotation of the photoconductor 40), are integrally formed on the endportions on the one side (scanning start side) and the other side(scanning end side) of the lens body 432. Shaft portions 452 and 462 oftorsion bar springs 450 and 460 are inserted into the support holes 441and 443 in the convex portions 440 and 442. The shaft portions 452 and462 are configured so as to not rotate inside the support holes 441 and443.

The torsion bar springs 450 and 460 include, from the top portions ofthe shaft portions 452 and 462, plate-shaped adjustment portions 454 and464 whose longitudinal direction coincides with the direction orthogonalto the shaft portions 452 and 462. When the adjustment portions 454 and464 are rotated about the shaft portions 452 and 462, the shaft portions452 and 462 twist, and a bending moment is generated in the convexportions 440 and 442 because of the reaction force. Additionally, due tothis bending moment, the cylindrical lens 430 bows.

Pins 501 and 502 are inserted into plural adjustment holes 498 and 499formed in a fixed portion 496 disposed spanning the distance between aside surface portion 492 and a side surface portion 494 of an opticalbox 490, and the adjustment portions 454 and 464 of the torsion barsprings 450 and 460 are caught on the pins 501 and 502. The adjustmentholes 498 and 499 are plurally formed in a circle around the supportholes 441 and 443 (the shaft portions 452 and 462 of the torsion barsprings 450 and 460) in the cylindrical lens 430. Additionally, bychanging the adjustment holes 498 and 499 into which the pins 501 and502 are to be inserted, the rotation amount of the adjustment portions454 and 464 of the torsion bar springs 450 and 460—that is, the bendingmoment generated in the convex portions 440 and 442 of the cylindricallens 430—can be adjusted to adjust the bowing amount of the cylindricallens 430.

The present invention is not limited to the preceding exemplaryembodiments and can be implemented in various aspects in a range thatdoes not depart from the gist of the invention.

For example, in the preceding exemplary embodiments, four light beams towhich the four photoconductors 40Bk, 40Y, 40M, and 40C are exposed wereemitted from one optical scanning device 14, 214, 314, or 414, but theinvention is not limited to this. For example, the image formingapparatus may also be disposed with one optical scanning device for eachof the photoconductors (for a total of four optical scanning devices).

Further, in the preceding exemplary embodiments, the image formingapparatus was disposed with the four photoconductors 40Bk, 40Y, 40M, and40C, but the invention is not limited to this. The image formingapparatus may also be disposed with three or less or five or morephotoconductors.

Further, in the preceding exemplary embodiments, as examples of opticalcomponents to which the invention may be applied, the invention wasapplied to the cylindrical mirrors 30, 230, and 330 and to thecylindrical lens 430, but the invention is not limited to this. Theinvention can also be applied to optical components that reflect orshape light beams, such as other lenses and mirrors of an opticalscanning device.

Moreover, in the preceding exemplary embodiments, the invention wasapplied to optical components of an optical scanning device of an imageforming apparatus, but the invention is not limited to this. Theinvention can also be applied to optical components that reflect orshape light beams, such as lens and mirrors used in other opticaldevices. For example, the invention can be applied to optical componentsused in barcode reading apparatus.

The foregoing description of the exemplary embodiments of the presentinvention has been provided for the purposes of illustration anddescription. It is not intended to be exhaustive or to limit theinvention to the precise forms disclosed. Obviously, many modificationsand variations will be apparent to practitioners skilled in the art. Theexemplary embodiments were chosen and described in order to best explainthe principles of the invention and its practical applications, therebyenabling others skilled in the art to understand the invention forvarious embodiments and with the various modifications as are suited tothe particular use contemplated. It is intended that the scope of theinvention be defined by the following claims and their equivalents.

1. An optical component bowing device, comprising: a bending momentgenerating structure including: extension members that extend in adirection substantially orthogonal to a longitudinal direction of anoptical component, the extension members being positioned adjacentlongitudinal end portions of the optical component; loading members thatload the extension members in a direction that is parallel to alongitudinal direction of the optical component, whereby displacement ofthe extension members generates a bending moment in a supported portionof the optical component that reflects or shapes a light beam; and areflective surface, wherein extension members on at least one end of theoptical component are T-shaped when seen in plan view in a directionorthogonal to the reflective surface.
 2. The optical component bowingdevice according to claim 1, wherein the loading members compriseadjustment screws for applying a load to the extension members to causethe displacement of the extension members.